Manual pump for intravenous fluids

ABSTRACT

A manually operable pump includes a fluid line operatively connected to a fluid source, and a manually operable actuator. A facilitator is used to facilitate flow of fluid from the fluid source through the fluid line. The facilitator is operably connected to the manually operable actuator. A piezoelectric system is operably connected to the manually operable actuator, and configured to capture energy from manual actuation of the manually operable actuator and regulate the speed of the facilitator.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation-in-part of U.S. patent application Ser. No. 12/748,700 filed on Mar. 29, 2010, which claims the benefit of priority of U.S. Provisional Application No. 61/164,763, filed on Mar. 30, 2009. Both applications are hereby incorporated in their entirety.

FIELD OF INVENTION

The present application relates to devices for infusing intravenous fluids. More particularly, the present application relates to a manual pump for infusing intravenous fluids into a subject.

BACKGROUND

In the medical and veterinary setting, the need may arise to rapidly infuse intravenous fluid into a subject. Saline and lactated ringers are examples of commonly used intravenous fluids. Such fluids may be used to maintain or elevate blood pressure and promote adequate perfusion. In the shock-trauma setting or in septic shock, fluid resuscitation is often first-line therapy to maintain or improve blood pressure.

Currently, a first responder, such as emergency medical technicians or military field medics, are known to administer intravenous fluids with a gravity drip, having a fluid bag, a fluid line, and an needle or intravenous catheter. When the needle or intravenous catheter is inserted into a subject, gravity causes the fluid to flow from the fluid bag, through the fluid line and needle, and into the subject. To increase the speed at which intravenous fluids are infused into the subject, the technician may apply pressure on the bag. Pressure may be applied by hand, by employing a blood pressure cuff, or other external pneumatic pressure device on the fluid bag itself.

Additionally, intraosseous (I.O.) lines have gained wider use in pediatric subjects, as well as adult subjects. Intraosseous infusion is a process of injection directly into the marrow of a subject's bone. Intraosseous lines often have a relatively slow rate of infusion.

There also exist several types of electronic pumps that infuse intravenous fluids. Such electronic pumps are often very costly and complex, and may require special training to operate. Further, such pumps may be delicate and not suited for field use. A first responder company will require several of these, adding to cost. Lastly, electronic pumps require a power source, such as a battery or wall socket, and may not necessarily be friendly to the environment.

SUMMARY OF THE INVENTION

In one embodiment, a manual intravenous pump includes a first housing having at least one roller disposed therein. The at least one roller is configured to engage a fluid line to facilitate flow of a fluid therethrough. The manual intravenous pump further includes a second housing having a manually operable actuator and a piezoelectric system operably connected to the manually operable actuator and operably connected to the at least one roller. The piezoelectric system captures energy supplied by manual actuation of the manually operable actuator. The piezoelectric system employs the captured energy to regulate a speed at which the at least one roller rotates.

In another embodiment, a manually operable pump includes a fluid line operatively connected to a fluid source, and a manually operable actuator. A facilitator is used to facilitate flow of fluid from the fluid source through the fluid line. The facilitator is operably connected to the manually operable actuator. A piezoelectric system is operably connected to the manually operable actuator, and configured to capture energy from manual actuation of the manually operable actuator and regulate the speed of the facilitator.

In yet another embodiment, an intravenous fluid pumping kit includes a fluid bag, a fluid line, and a pump. The pump includes a housing, and at least one roller configured to engage the fluid line, wherein rotation of the at least one roller facilitates a flow of fluid through the fluid line. The pump further includes a manually operable actuator operably connected to the at least one roller, such that manual actuation of the manual operable actuator causes the at least one roller to rotate.

BRIEF DESCRIPTION OF THE DRAWINGS

In the accompanying drawings, structures are illustrated that, together with the detailed description provided below, describe exemplary embodiments of the claimed invention.

In the drawings and description that follows, like elements are identified with the same reference numerals. It should be understood that elements shown as a single component may be replaced with multiple components, and elements shown as multiple components may be replaced with a single component. The drawings are not to scale and the proportion of certain elements may be exaggerated for the purpose of illustration.

FIG. 1 is a schematic drawing of a manual intravenous pump in combination with a fluid bag and a fluid line;

FIG. 2 is a top view of one embodiment of a manual intravenous pump having a crank;

FIG. 3 is a top cutaway view of one embodiment of a manual intravenous pump having a crank and rotary chambers;

FIG. 4 is a top cutaway view of an alternative embodiment of a manual intravenous pump having a crank and a bulb;

FIG. 5 is an exploded perspective view of an alternative embodiment of a manual intravenous pump having an actuator housing and a reservoir housing;

FIGS. 6A and 6B are cross-sections of one embodiment of a reservoir housing having a pair of asymmetric diaphragm pumps;

FIGS. 7A and 7B are cross-sections of one embodiment of a reservoir housing having a pair of symmetric diaphragm pumps;

FIG. 8 is a side view of an alternative embodiment of a manual intravenous pump having a trigger;

FIG. 9 is a side cutaway view of an alternative embodiment of a manual intravenous pump having a trigger and a bulb;

FIG. 10 is a side cutaway view of another alternative embodiment of a manual intravenous pump having a trigger and a piston;

FIG. 11 is a side cutaway view of another alternative embodiment of a manual intravenous pump having a trigger and rotary chambers;

FIG. 12 is a perspective view of an exemplary twin spring motor for use in a manual intravenous pump having a trigger;

FIG. 13 is a perspective view of an exemplary sextupled spring motor for use in a manual intravenous pump having a trigger;

FIG. 14 is a perspective view of another alternative embodiment of a manual intravenous pump having at least one pivoting handle;

FIG. 15 is a side view of the manual intravenous pump having at least one pivoting handle;

FIG. 16 is an exploded perspective view of an actuator housing of the manual intravenous pump having at least one pivoting handle;

FIG. 17 is a cross section of the actuator housing of the manual intravenous pump having at least one pivoting handle;

FIG. 18 is a cross section of a reservoir housing for a manual intravenous pump;

FIG. 19 is a cut away view of an alternative embodiment of a pump for use in a manual intravenous pump;

FIG. 20 is a cross section of a fluid line housing for a manual intravenous pump;

FIG. 21 is an alternative embodiment of a fluid line housing for a manual intravenous pump; and

FIG. 22 is a schematic drawing of an alternative embodiment of a manual intravenous pump having a piezoelectric system.

DETAILED DESCRIPTION

Multiple embodiment of intravenous pumps are shown and described herein. It should be understood that the disclosed pumps may be employed to pump any known intravenous fluids, including, without limitation, saline, lactated ringers, colloid solution, platelets, and blood. Further, the use of the disclosed pumps is not limited to the intravenous application of fluids. It should be understood that the pumps may be used, for example, for wound irrigation or other cleaning or sterilization purposes. For such uses, the pumps may be used with water, alcohol, or other sterilants.

FIG. 1 is a schematic drawing of a manual intravenous pump 100 in combination with a fluid bag B and a fluid line. In the illustrated embodiment, the fluid line includes a first line L₁ and a second line L₂. The first fluid line L₁ is connected to an output of the fluid bag B and an input 110 of the manual intravenous pump 100. The first fluid line L₁ leads to an internal fluid reservoir (not shown) in the manual intravenous pump 100. The manual intravenous pump 100 further includes one or more mechanisms (not shown) to facilitate the flow of fluid through the internal fluid reservoir. In one embodiment, the input 110 of the manual intravenous pump 100 is a one-way valve. In alternative embodiments, the input may be a 2-way valve, or an adjustable, bi-directional valve.

The second fluid line L₂ is connected to an output 120 of the manual intravenous pump 100 and leads to a subject, usually by a needle or intravenous catheter. Alternatively, the manual intravenous pump 100 may employ central line catheters and interosseous lines. In one embodiment, the output 120 is also a one-way valve. One-way valves allows the fluid only to flow from the fluid bag B, to the subject, and not in a reverse direction. In alternative embodiments, however, the output may be a 2-way valve, or an adjustable, bi-directional valve.

The manual intravenous pump 100 may be used in-line (i.e., in series) as described above. Alternatively, the manual intravenous pump 100 may also be used in a bypass-type configuration (i.e., in parallel) to allow a gravity drip to continue.

The manual intravenous pump 100 further includes a manually operable actuator (not shown), configured to force fluid from the input 110 of the manual intravenous pump 100 to the output 120. Various types of manually operable actuators may be employed. Exemplary manual operable actuators are discussed below. These examples are not intended to be limiting.

FIG. 2 illustrates a top view of one embodiment of a manual intravenous pump 200 having an input 210, an output 220, and a body 230. In this embodiment, the manually operable actuator is a crank 240. This type of manual intravenous pump may be referred to as a “crank design,” “crank pump,” or “hand crank.” The crank 240 includes a lever arm 250 rotatably connected to the body 230 of the manual intravenous pump 200. In the illustrated embodiment, the crank 240 further includes a handle 260 connected to the lever arm 250. The handle 260 may be rotatably or fixedly connected to the lever arm 250. In one embodiment, the crank 240 is a single, unitary piece including a lever arm portion and handle portion.

In the illustrated embodiment, the manual intravenous pump 200 further includes a pair of handles 270. The handles 270 may be solid or flexible. The handles may be ergonomically shaped for the comfort of the user. Further, the handles may be located in an ergonomic position for the comfort of the user. In an alternative embodiment (not shown), the manual intravenous pump includes three or more handles. In another alternative embodiment (not shown), the manual intravenous pump includes a single handle. In yet another alternative embodiment (not shown), the manual intravenous pump does not include any handles, and could have contours that are designed for ergonomic handling.

With continued reference to FIG. 2, the body 230 of the manual intravenous pump 200 has an approximately cubic shape, with rounded edges. However, it should be understood that this shape is merely exemplary, and any shape may be employed. In one embodiment, the body may have an ergonomic shape.

Although FIG. 2 is described as a top view, it should be understood that the crank 240 and optional handles 270 may be located on any surface of the manual intravenous pump 200, such as a side or bottom surface. Further, in one embodiment, the manual intravenous pump 200 is designed to be positioned in multiple orientations, so that the operator may position the device in a comfortable orientation for operation.

The manual intravenous pump 200 may be constructed of various materials. Exemplary materials include polymeric materials and metal materials. Exemplary metal materials include, without limitation, steel, nickel aluminum, copper, iron, and other metals and alloys. Exemplary polymeric materials include, without limitation, EPDM Rubber, latex, polypropylene, polyethylene, and blends of the same. In one embodiment, where the manual intravenous pump is configured for field use (i.e., in an ambulance, or at an accident site), the device may be constructed of materials that are lightweight and durable. Of course, such materials may also be suitable for a device configured for clinical use. In one embodiment, the casing 230, the crank 240, and the handles 270 are all constructed of substantially the same material. In an alternative embodiment, one or more of these components are constructed of different materials.

FIG. 3 is a top cutaway view of one embodiment of a manual intravenous pump 300. The illustrated embodiment is one example of the internal components of the crank design of a manual intravenous pump 200 shown in FIG. 2.

In the illustrated embodiment, the crank 240 is connected to a rod 310 having a plurality of partitions 320 extending therefrom. The rod 310 and partitions 320 are positioned inside a cylinder 330 that defines an internal fluid reservoir of the manual intravenous pump 300. The cylinder 330 has a first opening 340 in fluid communication with the input 210 of the manual intravenous pump 300 and a second opening 350 in fluid communication with the output 220 of the manual intravenous pump 300. The rod 310 and partitions 320 form a plurality of rotary chambers 360 in the cylinder 330. In the illustrated embodiment, the rod 310 includes three partitions 320 extending therefrom, which form three rotary chambers 360 in the cylinder 330. However, it should be understood that any number of partitions may be employed, including a single partition.

In addition to the components shown, various gear configurations may be employed to create a mechanical advantage and/or cause the rod 310 and partitions 320 to rotate at a rate different from the rate at which the crank 240 is turned.

Various materials may be used to construct the rod 310, partitions 320, and cylinder 330. Exemplary materials include polymeric materials and metal materials. In one embodiment, the rod 310, partitions 320, and cylinder 330 are constructed of polymeric materials that resist corrosion after prolonged exposure to saline solutions and other commonly used intravenous fluids. In one embodiment, the rod 310, partitions 320, and cylinder 330 are all constructed of substantially the same material. In an alternative embodiment, one or more of these components are constructed of different materials.

With continued reference to FIG. 3, the partitions 320 extend from the rod 310 to an inner surface of the cylinder 330. In one embodiment, at least the ends of the partitions are constructed of rubber, or another pliable, non-porous material, to form a seal. It should be understood, however, that various other materials may be employed. In an alternative embodiment, the partitions 320 do not extend to the inner surface of the cylinder 330.

In operation, the input 210 of the manual intravenous pump 300 is connected to a first fluid line leading to a fluid bag, and the output 220 is connected to a fluid line leading to a subject. In one embodiment, both the input 210 and the output 220 are one-way valves. In one embodiment, when a fluid line is connected to the input 210, fluid immediately begins to flow from the fluid bag, through the fluid line and input 210, and into the first of the plurality of chambers 360. In an alternative embodiment, fluid will not begin to flow until the input 210 is opened (e.g., by turning or pressing a valve).

Once the fluid lines have been connected to the fluid bag, the manual intravenous pump 300, and the subject, and the fluid has begun to flow, an operator may turn the crank 240 of the manual intravenous pump 300. As the crank 240 is turned, the partitions 320 rotate at a corresponding speed and force the fluid from the first opening 340 of the cylinder 330 towards the second opening 350. In the illustrated embodiment, the crank 240 may be turned in either a clockwise or a counter-clockwise direction. Turning the crank 240 at a faster rate may increase the rate at which fluid flows through the output 350 and to a subject, while turning the crank 240 at a slower rate may decrease the rate at which fluid flows through the output 220 and to a subject. The operator may control the speed at which the crank 240 is turned, according to perceived need.

FIG. 4 is a top cutaway view of an alternative embodiment of a manual intravenous pump 400. The illustrated embodiment is another example of the internal components of the crank design of a manual intravenous pump 200 shown in FIG. 2.

In the illustrated embodiment, the crank 240 is connected to a disc 410 having a plurality of spaced apart, projections 420 extending therefrom. The disc 410 may be substantially circular or eccentric. The manual intravenous pump 400 further includes an internal fluid line 430 having a bulb 440 that defines an internal fluid reservoir of the manual intravenous pump 400. The internal fluid line 430 is in fluid communication with both the input 210 and the output 220 of the manual intravenous pump 400. The disc 410 and projections 420 are positioned adjacent the bulb 440, such that the projections 420 contact and deform the bulb 440 when the disc 410 is rotated. In the illustrated embodiment, the disc 410 includes three projections 420 extending therefrom. However, it should be understood that any number of projections may be employed, including a single projection.

In the illustrated embodiment, the bulb 440 abuts a platform to facilitate compression upon contact with a projection 420. In an alternative embodiment (not shown), the bulb 440 may abut a wall of the manual pump 400. In another alternative embodiment (not shown), the bulb does not abut any surfaces.

In addition to the components shown, various gear configurations may be employed to create a mechanical advantage and/or cause the disc 410 and projections 420 to rotate at a rate different from the rate at which the crank 240 is turned.

With continued reference to FIG. 4, the bulb 440 is constructed of rubber, or another pliable, non-porous material. It should be understood, however, that various other materials may be employed. Further, various materials may be used to construct the disc 410 and projections 420. Exemplary materials include polymeric materials and metal materials. In one embodiment, the disc 410 and projections 420 are constructed of substantially the same material. For example, the disc 410 and projections 420 may be one unitary member. In an alternative embodiment, the disc 410 and projections 420 are constructed of different materials.

In operation, the input 210 of the manual intravenous pump 400 is connected to a first fluid line leading to a fluid bag, and the output 220 is connected to a fluid line leading to a subject. In one embodiment, both the input 210 and the output 220 are one-way valves. In one embodiment, when a fluid line is connected to the input 210, fluid immediately begins to flow from the fluid bag, through the fluid line and input 210, and into the internal fluid line 430. In an alternative embodiment, fluid will not begin to flow until the input 210 is opened (e.g., by turning or pressing a valve).

In the illustrated embodiment, once the fluid lines have been connected to the fluid bag, the manual intravenous pump 400, and the subject, and the fluid has begun to flow, an operator may turn the crank 240 of the manual intravenous pump 400 in a counterclockwise direction. As the crank 240 is turned in a counter-clockwise direction, the disc 410 and projections 420 rotate at a corresponding speed and act as a cam on the bulb 440, compressing the bulb 440 and forcing the fluid towards the output 220. Because the projections 420 are spaced apart, spacing allows the bulb 440 to inflate with fluid by negative pressure before the next projection 420 compresses the bulb 440.

It should be understood that, although in the illustrated embodiment a counter-clockwise rotation of the crank 240 is required to force fluid towards the output 220, the components may be re-oriented to require clockwise rotation. In either embodiment, rotation of the crank in a first direction will force fluid to move in a first direction, while rotation of the crank in the opposite direction will force fluid to move in an opposite direction. To prevent the crank from being rotated in an undesired direction, a ratchet and pawl (not shown) or other know stopping mechanism may be employed.

It should be understood that turning the crank 240 at a faster rate may increase the rate at which fluid flows through the output 220 and to a subject, while turning the crank 240 at a slower rate may decrease the rate at which fluid flows through the output 220 and to a subject. The operator may control the speed at which the crank 240 is turned, according to perceived need.

FIG. 5 illustrates an exploded perspective view of an alternative embodiment of a manual intravenous pump 500 having an actuator housing 505 and at least one reservoir housing 510. The actuator housing 505 includes a manually operable member in the form of a crank 515 having a lever arm 520 and a handle 525. The handle 525 may be fixedly or rotatably connected to the lever arm 520. In an alternative embodiment (not shown), other known manually operable members may be employed in place of a crank.

In the illustrated embodiment, the lever arm 520 is operatively connected to a shaft 530 that turns a series of gears 535 mounted on a base 540. While two gears are shown in the illustrated embodiment, it should be understood that three or more gears may be employed. Alternatively, gears may be omitted.

The series of gears 535 rotates a disc 545 having a plunger 550 pivotally attached thereto. The plunger is one example of a facilitating member configured to facilitate a flow of fluid through a reservoir. The plunger 550 is configured to operatively connect to a pump (not shown) in the reservoir housing 510. The actuator housing 505 may further include a second disc and plunger (not shown) mounted on the opposite side of the base 540 and configured to operatively connect to a second pump (not shown) in the reservoir housing 510.

In the illustrated embodiment, the gears 535 have a fixed gear ratio. In an alternative embodiment (not shown), a gear shift mechanism may be employed to vary the gear ratio. In such an embodiment, an operator may choose to shift gears to increase or decrease the flow of fluid.

The reservoir housing 510 may be configured to be removably attached to the actuator housing 505. In such an embodiment, the reservoir housing 510 may be removed and replaced with a replacement reservoir housing (not shown). For example, the reservoir housing 510 may be replaced after each use for sterility or safety reasons, or to comply with FDA standards, hospital standards, or other standards. In such an embodiment, the reservoir housing 510 may be kept in sterile packaging prior to use. Additionally, the reservoir housing 510 may be filled with fluid prior to packaging, such that no priming is required when a new reservoir housing 510 is attached to the actuator housing 505. In an alternative embodiment (not shown), the reservoir housing may be permanently attached to the actuator housing.

In the illustrated embodiment, the reservoir housing 510 includes a set of rails 555 on opposing sides, configured to slidably receive prongs 560 of the base 540 of the actuator housing 505. The prongs 560 and the sides of the reservoir housing 510 have corresponding apertures 565 configured to receive fasteners 570. In the illustrated embodiment, the fasteners 570 are shown as screws. However, it should be understood that any fasteners may be employed. Exemplary fasteners include bolts, pins, ties, and other known fasteners. In an alternative embodiment (not shown), the apertures and fasteners may be omitted. Instead, the reservoir housing 510 may be attached to the actuator housing 505 by a press fit, a snap fit, clamps, or other attachment means.

The actuator housing 510 includes two input lines (not shown) and two output lines 575. The two input lines may be connected to a single input line (not shown) by a y-connector (not shown). Similarly, the two output lines 575 may be connected to a single output line (not shown) by a y-connector (not shown).

The internal components of two exemplary embodiments of reservoir housings 510 are shown in FIGS. 6A, 6B, 7A, and 7B.

FIGS. 6A and 6B illustrate cross-sections of one embodiment of a reservoir housing 600. The reservoir housing 600 includes two fluid reservoirs defined by a first asymmetric diaphragm pump 610 a and a second asymmetric diaphragm pump 610 b. The first and second asymmetric diaphragm pumps 610 a,b are collapsible bellows or diaphragms that inflate and deflate with fluid. The first asymmetric diaphragm pump 610 a is connected to a first piston 620 a, a first input line 630 a, and a first output line 640 b. The second asymmetric diaphragm pump 610 b is connected to a second piston 620 b, a second input line 630 b, and a second output line 640 b.

In the illustrated embodiment, the first asymmetric diaphragm pump 610 a is out of phase with the second asymmetric diaphragm pump 610 b. When the first piston 620 a collapses the first asymmetric diaphragm pump 610 a, as shown in FIG. 6A, fluid in the first asymmetric diaphragm pump 610 a is forced through the first output line 640 a. The second piston 620 b opens the second asymmetric diaphragm pump 610 b concurrently, and fluid flows through the second input line 630 b into the second asymmetric diaphragm pump 610 b. As the cycle continues, as shown in FIG. 6B, the second piston 620 b collapses the second asymmetric diaphragm pump 610 b, forcing fluid out of the second diaphragm pump 610 b and through the second output line 640 b. The first piston 620 a opens the first asymmetric diaphragm pump 610 a concurrently, and fluid flows through the first input line 630 a into the first asymmetric diaphragm pump 610 a. Each of the first and second asymmetric diaphragm pumps 610 a,b may have check valves (not shown) associated therewith.

In one embodiment, fluid would flow through the asymmetric diaphragm pumps 610 a,b and the output lines 640 a,b, even when the pumps were not being actuated. In an alternative embodiment, fluid would only flow through the asymmetric diaphragm pumps 610 a,b upon actuation. In another alternative embodiment (not shown), the system includes a flow regulation mechanism (i.e., a safety, or an on/off switch) that would allow an operator to prevent fluid from flowing through the output lines 640 a,b. Such a flow regulation mechanism may be located on the reservoir housing 600.

In an alternative embodiment (not shown), the first and second asymmetric diaphragm pumps 610 a,b may operate in phase. In another alternative embodiment (not shown), the reservoir housing 600 includes a single asymmetric diaphragm pump. In yet another alternative embodiment (not shown), the reservoir housing 600 includes three or more asymmetric diaphragm pumps.

FIGS. 7A and 7B illustrate cross-sections of another embodiment of a reservoir housing 700. The reservoir housing 700 is substantially the same as the reservoir housing 700, except that it includes two fluid reservoirs defined by a first symmetric diaphragm pump 710 a and a second symmetric diaphragm pump 710 b. The first and second symmetric diaphragm pumps 710 a,b are collapsible bellows or diaphragms that inflate and deflate with fluid. The first symmetric diaphragm pump 710 a is connected to a first piston 720 a, a first input line 730 a, and a first output line 740 a. The second symmetric diaphragm pump 710 b is connected to a second piston 720 b, a second input line 730 b, and a second output line 740 b.

In the illustrated embodiment, the first symmetric diaphragm pump 710 a is out of phase with the second symmetric diaphragm pump 710 b, and the pumps operate in the same manner as described in FIGS. 7A and 7B. In an alternative embodiment (not shown), the first and second symmetric diaphragm pumps 710 a,b may operate in phase. In another alternative embodiment (not shown), the reservoir housing 700 includes a single symmetric diaphragm pump. In yet another alternative embodiment (not shown), the reservoir housing 700 includes three or more symmetric diaphragm pumps.

FIG. 8 illustrates a side view of an alternative embodiment of a manual intravenous pump 800 having an input 810, an output 820, and a body 830. In this embodiment, the manually operable actuator is a trigger 840. This type of manual intravenous pump may be referred to as a “trigger design,” “trigger pump,” or a “manual piston.” The trigger 840 may be configured to pivot or slide transversely with respect to the body 830 of the manual intravenous pump 800. In one embodiment, the trigger 840 is sized to accommodate a single finger of an operator. In an alternative embodiment, the trigger 840 is sized to accommodate two or more fingers of an operator.

With continued reference to FIG. 8, the body 830 of the manual intravenous pump 800 bears resemblance to a pistol. However, it should be understood that this shape is merely exemplary, and any shape may be employed. In one embodiment, the body may have an ergonomic shape.

Although FIG. 8 is described as a side view, it should be understood that the manual intravenous pump 800 may be positioned in multiple orientations, so that the operator may position the device in a comfortable orientation for operation.

The manual intravenous pump 800 may be constructed of various materials. Exemplary materials include polymeric materials and metal materials. Exemplary metal materials include, without limitation, steel, nickel aluminum, copper, iron, and other metals and alloys. Exemplary polymeric materials include, without limitation, EPDM Rubber, polypropylene, polyethylene, and blends of the same. In one embodiment, where the manual intravenous pump is configured for field use (i.e., in an ambulance, or at an accident site), the device may be constructed of materials that are lightweight and durable. Of course, such materials may also be suitable for a device configured for clinical use. In one embodiment, the casing 830 and the trigger 840 are all constructed of substantially the same material. In an alternative embodiment, one or more of these components are constructed of different materials.

FIG. 9 is a side view of internal components of one embodiment of a manual intravenous pump 900. The illustrated embodiment is one example of the internal components of the trigger design of a manual intravenous pump 800 shown in FIG. 8.

In the illustrated embodiment, the trigger 840 is pivotally connected to a series of gears 910, which are, in turn, connected to a disc 920 having a plurality of spaced apart, projections 930 extending therefrom. In the illustrated embodiment, two gears are shown. However, it should be understood that any number of gears may be employed. In an alternative embodiment (not shown), no gears are employed, and the trigger is instead directly connected to the disc.

The illustrated manual intravenous pump 900 further includes an internal fluid line 940 having a bulb 950 that defines an internal fluid reservoir. The internal fluid line 940 is in fluid communication with both the input 810 and the output 820 of the manual intravenous pump 900. The disc 920 and projections 930 are positioned adjacent the bulb 950, such that the projections 930 contact and deform the bulb 950 when the disc 920 is rotated. In the illustrated embodiment, the disc 920 includes three projections 930 extending therefrom. However, it should be understood that any number of projections may be employed, including a single projection.

In the illustrated embodiment, the bulb 950 abuts a platform to facilitate compression upon contact with a projection 930. In an alternative embodiment (not shown), the bulb 950 may abut a wall of the manual pump 900. In another alternative embodiment (not shown), the bulb does not abut any surfaces.

With continued reference to FIG. 9, the bulb 950 is constructed of rubber, or another pliable, non-porous material. It should be understood, however, that various other materials may be employed. Further, various materials may be used to construct the disc 920 and projections 930. Exemplary materials include polymeric materials and metal materials. In one embodiment, the disc 920 and projections 930 are constructed of substantially the same material. For example, the disc 920 and projections 930 may be one unitary member. In an alternative embodiment, the disc 920 and projections 930 are constructed of different materials.

In operation, the input 810 of the manual intravenous pump 900 is connected to a first fluid line leading to a fluid bag, and the output 820 is connected to a fluid line leading to a subject. In one embodiment, both the input 810 and the output 820 are one-way valves. In one embodiment, when a fluid line is connected to the input 810, fluid immediately begins to flow from the fluid bag, through the fluid line and input 810, and into the internal fluid line 940. In an alternative embodiment, fluid will not begin to flow until the input 810 is opened (e.g., by turning or pressing a valve).

In the illustrated embodiment, once the fluid lines have been connected to the fluid bag, the manual intravenous pump 900, and the subject, and the fluid has begun to flow, an operator may squeeze the trigger 840 of the manual intravenous pump 900. As the trigger 840 is squeezed, gears 910 cause the disc 920 and projections 930 to rotate and act as a cam on the bulb 950, compressing the bulb 950 and forcing the fluid towards the output 820. Because the projections 930 are spaced apart, spacing allows the bulb 950 to inflate with fluid by negative pressure before the next projection 930 compresses the bulb 950. When the trigger 840 is released, a ratcheting mechanism (not shown) or other such mechanism may be employed to prevent the disc 920 and projections 930 from moving in the reverse direction.

It should be understood that squeezing the trigger 840 at a faster rate may increase the rate at which fluid flows through the output 820 and to a subject, while squeezing the trigger 840 at a slower rate may decrease the rate at which fluid flows through the output 820 and to a subject. The operator may control the speed at which the trigger 840 is squeezed, according to perceived need.

FIG. 10 is a cutaway side view of internal components of one embodiment of a manual intravenous pump 700. The illustrated embodiment is one example of the internal components of the trigger design of a manual intravenous pump 800 shown in FIG. 8.

In the illustrated embodiment, the trigger 840 is pivotally connected to the casing 830 and is further connected to a piston 1010. The piston 1010 is biased towards the trigger 840 by a biasing mechanism 1020. In the illustrated embodiment, the biasing mechanism 1020 is shown as a spring. However, it should be understood that any known biasing mechanism may be employed. The piston 1010 and biasing mechanism 1020 are housed in a cylinder 1030 that is part of a larger fluid reservoir 1040. The fluid reservoir is connected to the input 810 and output 820. In the illustrated embodiment, both the input 810 and output 820 are one-way valves.

In operation, an operator squeezes the trigger 840, which pushes the piston 1020 into the cylinder 1030, compressing the biasing mechanism 1020. When the piston 1020 is pushed into the cylinder 1030, the volume of the fluid reservoir 1040 is reduced, forcing fluid through the output 820. When the trigger is released, the biasing mechanism 1020 pushes the piston 1020 back out of the cylinder, expanding the volume of the fluid reservoir 1040 and drawing more fluid in through the input 810. The one way valves of the input 810 and output 820 prevent the fluid from flowing in an undesired direction.

FIG. 11 is a side cutaway view of one embodiment of a manual intravenous pump 1100. The illustrated embodiment is another example of the internal components of the trigger design of a manual intravenous pump 800 shown in FIG. 8.

In the illustrated embodiment, the trigger 840 is connected to a series of gears 1110, which are connected rod 1120 having a plurality of partitions 1130 extending therefrom. While two gears 1110 are illustrated, it should be understood that three or more gears may be employed. Alternative, the trigger 840 may be directly connected to the rod 1120 without the use of intervening gears.

With continued reference to FIG. 11, the rod 1120 and partitions 1130 are positioned inside a cylinder 1140 that defines an internal fluid reservoir. The cylinder 1140 has a first opening 1150 in fluid communication with the input 810 of the manual intravenous pump 1100 and a second opening 1160 in fluid communication with the output 820 of the manual intravenous pump 1100. The rod 1120 and partitions 1130 form a plurality of rotary chambers 1170 in the cylinder 1140. In the illustrated embodiment, the rod 1120 includes three partitions 1130 extending therefrom, which form three rotary chambers 1170 in the cylinder 1140. However, it should be understood that any number of partitions may be employed, including a single partition.

In addition to the components shown, various gear configurations may be employed to create a mechanical advantage and/or cause the rod 1120 and partitions 1130 to rotate at a rate different from the rate at which the trigger 840 is squeezed.

With continued reference to FIG. 11, the partitions 1130 extend from the rod 1120 to an inner surface of the cylinder 1140. In one embodiment, at least the ends of the partitions are constructed of rubber, or another pliable, non-porous material, to form a seal. It should be understood, however, that various other materials may be employed. In an alternative embodiment, the partitions 1130 do not extend to the inner surface of the cylinder 1140.

Various materials may be used to construct the rod 1120, partitions 1130, and cylinder 1140. Exemplary materials include polymeric materials and metal materials. In one embodiment, the rod 1120, partitions 1130, and cylinder 1140 are constructed of polymeric materials that resist corrosion after prolonged exposure to saline solutions and other commonly used intravenous fluids. In one embodiment, the rod 1120, partitions 1130, and cylinder 1140 are all constructed of substantially the same material. In an alternative embodiment, one or more of these components are constructed of different materials.

In operation, the input 810 of the manual intravenous pump 1100 is connected to a first fluid line leading to a fluid bag, and the output 820 is connected to a fluid line leading to a subject. In one embodiment, both the input 810 and the output 820 are one-way valves. In one embodiment, when a fluid line is connected to the input 810, fluid immediately begins to flow from the fluid bag, through the fluid line and input 810, and into the first of the plurality of chambers 1170. In an alternative embodiment, fluid will not begin to flow until the input 810 is opened (e.g., by turning or pressing a valve).

Once the fluid lines have been connected to the fluid bag, the manual intravenous pump 1100, and the subject, and the fluid has begun to flow, an operator may squeeze the trigger 840 of the manual intravenous pump 1100. As the trigger 840 is squeezed, the partitions 1130 rotate at a corresponding speed and force the fluid from the first opening 1150 of the cylinder 1140 towards the second opening 1160. Squeezing the trigger 840 at a faster rate may increase the rate at which fluid flows through the output 820 and to a subject, while squeezing the trigger 840 at a slower rate may decrease the rate at which fluid flows through the output 820 and to a subject. The operator may control the speed at which the trigger 840 is squeezed, according to perceived need.

In another alternative embodiment, the trigger pump may employ one or more spring motors to facilitate pumping. For example, FIG. 12 illustrates a perspective view of an exemplary twin spring motor 1200 which may be employed in a trigger pump. As another example, FIG. 13 illustrates a perspective view of an exemplary sextupled spring motor 1300 which may be employed in a trigger pump. In either example, the spring motor may be configured to coil and store energy when a trigger is depressed. When the trigger is released, the spring motor releases energy to compress a pump. In yet another embodiment, an electric motor may be employed to actuate the pumps.

In still another alternative embodiment (not shown), the trigger pump employs a separate reservoir housing, such as the reservoir housing 505 shown in FIG. 5, reservoir housing 600 shown in FIGS. 6A,B, or reservoir housing 700 shown in FIGS. 7A,B. Such a reservoir housing may be removably attached to the device, such that the reservoir housing may be removed and replaced as desired.

FIGS. 14 and 15 illustrate a perspective view and side view, respectively, of another alternative embodiment of a manual intravenous pump 1400 having an actuator housing 1405 and at least one reservoir housing 1410. The actuator housing 1405 includes a manually operable member in the form of a pivotal handle 1415 that is pivotally connected to a stationary handle 1420. Accordingly, this type of manual intravenous pump may be referred to as a “pivoting handle design” or “pivoting handled pump.” In this embodiment, the pump is actuated by pivoting the pivotal handle 1415 towards the stationary handle 1420. In an alternative embodiment (not shown), the actuator housing may include two pivotal handles.

The reservoir housing 1410 may be configured to be removably attached to the actuator housing 1405. In such an embodiment, the reservoir housing 1410 may be removed and replaced with a replacement reservoir housing (not shown). For example, the reservoir housing 1410 may be replaced after each use for sterility or safety reasons, or to comply with FDA standards, hospital standards, or other standards. In such an embodiment, the reservoir housing 1410 may be kept in sterile packaging prior to use. Additionally, the reservoir housing 1410 may be filled with fluid prior to packaging, such that no priming is required when a new reservoir housing 1410 is attached to the actuator housing 1405. In an alternative embodiment (not shown), the reservoir housing may be permanently attached to the actuator housing.

FIG. 16 illustrates an exploded perspective view of the actuator housing 1405 pivoting handled pump 1400. In the illustrated embodiment, the actuator housing includes a first actuator housing 1405 a that is fastened to a second actuator housing 1405 b by a plurality of fasteners. In addition to housing the pivotal handle 1415 and the stationary handle 1420, the actuator housing additionally houses a first gear 1425 having teeth configured to engage corresponding teeth of the pivotal handle 1415. The teeth of the first gear 1425 are further configured to engage teeth of a second gear 1430, which rotates about an axis of a spring loaded gear box 1435. The spring loaded gear box 1435 is configured to store and release energy, using springs such as those shown in FIGS. 12 and 13. While the illustrated embodiment shows two gears 1425, 1430, it should be understood that a single gear may be employed. In an alternative embodiment (not shown), three or more gears may be employed.

FIG. 17 illustrates a cross-section of the actuator housing 1405, and further shows the pivotal handle 1415 engaging the first gear 1425, which, in turn, engages the second gear 1430. The pivotal handle 1415 is connected to a biasing member, such as a spring, that biases the pivotal handle 1415 away from the stationary handle 1420. In one embodiment, the pivotal handle 1415 is configured such that its teeth engage the teeth of the first gear 1425 when the pivotal handle 1415 is pivoted towards the stationary handle 1420, but the teeth disengage when the pivotal handle 1415 pivots away from the stationary handle 1420. In this embodiment, a large amount of energy may be stored at one time, which may then be released by the spring loaded gear box. In an alternative embodiment, the teeth of the pivotal handle 1415 remain engaged with the teeth of the first gear 1425 when the pivotal handle pivots away from the stationary handle 1420.

FIG. 18 illustrates a cross section of the reservoir housing 1410. In the illustrated embodiment, the reservoir housing has substantially the same components as the reservoir housing 700, including first and second symmetric diaphragm pumps 1440 a,b connected to first and second input lines 1445 a,b and first and second output lines 1450 a,b. In the illustrated embodiment, the first and second symmetric diaphragm pumps 1440 a,b operate out of phase with respect to each other. In an alternative embodiment (not shown), the first and second symmetric diaphragm pumps 1440 a,b operate in phase with respect to each other. In another alternative embodiment (not shown), asymmetric diaphragm pumps may be employed.

FIG. 19 illustrates a cut away view of an alternative embodiment of a pump 1900 for use in a manual intravenous pump. The pump 1900 is an axial flow pump having an outer housing 1910 and a bladed rotor 1920, and may be employed with any embodiment of a manual intravenous pump described herein. The pump 1900 may be employed as a single pump, or in combination with one more additional pumps.

In the illustrated embodiment, the outer housing 1910 has a first a projection 1930 along a first axis and the rotor has a second projection 1940. The second projection 1940 may be located on the first axis, or it may be located along a second axis different from the first axis. The bladed rotor 1920 is disposed in the outer housing 1910 in a manner providing clearance between an outer surface of the bladed rotor 1920 and an inner surface of the outer housing 1910. This clearance defines one or more flow channels 1950 for a fluid.

The bladed rotor 1920 further includes at least one hydrodynamic bearing. In the illustrated embodiment, the rotor includes a first hydrodynamic bearing 1960 and a second hydrodynamic bearing 1970. The first and second hydrodynamic bearings 1960, 1970 are larger and wider than the area between blades where fluid flows. In an alternative embodiment (not shown), the first and second hydrodynamic bearings 1960, 1970 are narrower than the area between blades where fluid flows.

The bladed rotor 1920 is configured to rotate within the outer housing 1910, thereby facilitating a flow of fluid. The bladed rotor 1920 may be rotated by activation of a manual actuator or with the use of magnets or electronics.

FIG. 20 illustrates a cross section of a fluid line housing 2000 for a manual intravenous pump. In the illustrated embodiment, the fluid line housing 2000 that can be used with an actuator housing (such as actuator housing 1405) instead of a reservoir housing. However, it should be understood that the fluid line housing may be incorporated in a single housing that includes both an actuator and a fluid line.

Fluid line housing 2000 includes a fluid line 2010. In the illustrated embodiment, the fluid line is a single line that is partially disposed within the housing 2000, but extends beyond the boundaries of the housing. The fluid line 2010 has a first end operably connected to a fluid source (not shown) and a second end operably connected to an intravenous needle (not shown). The fluid line 2010 may be disposed in a slot in the fluid line housing 2000 such that the fluid line 2010 may be inserted and removed from the fluid line housing 2000 without any of the fluid coming into contact with the fluid line housing 2000. In such an embodiment, the fluid line housing 2000 may be reused with multiple fluid lines for multiple patients without contamination. In an alternative embodiment (not shown), the fluid line is disposed inside the fluid line housing and has a first end configured to be connected to an input line and a second end configured to be connected to an output line.

The fluid line housing 2000 further includes a plurality of rollers 2020. In the illustrated embodiment, the fluid line housing 2000 includes six rollers 2020. However, it should be understood that any number of rollers may be employed. Each of the rollers 2020 is operably connected to a manually operable actuator (such as those manually operable actuators described above) such as through a series of gears. Each roller 2020 is slightly elongated, such that as each roller turns, it comes into and out of engagement with the fluid line 2010. The part of fluid line 2010 under compression closes (or occludes) thus forcing the fluid to move through the fluid line 2010. When the roller comes out of engagement with the fluid line 2010, the fluid line opens to its natural state fluid flow is induced to that section of the fluid line 2010. Such a process may be referred to as “peristalsis” and the rollers 2020 may therefore be referred to as “peristaltic rollers.”

FIG. 21 illustrates a cross section of an alternative embodiment of a fluid line housing 2100 for a manual intravenous pump. It should be understood that the details of the illustrated fluid line housing may also be incorporated in a single housing that includes both an actuator and a fluid line.

Fluid line housing 2100 includes a fluid line 2110. In the illustrated embodiment, the fluid line 2110 is disposed inside the fluid line housing and has a first end configured to be connected to an input line and a second end configured to be connected to an output line. In an alternative embodiment (not shown), the fluid line is a single line that is partially disposed within the housing, but extends beyond the boundaries of the housing. In such an embodiment, the fluid line may be disposed in a slot in the fluid line housing.

The fluid line 2110 has an arcuate shape, such that the first end and second end of the fluid line 2110 are both disposed on the same side of the fluid line housing 2100.

The fluid line housing 2100 further includes a rotary device 2120. Although the rotary device 2120 is elongated and non-circular, it may still be referred to as a “roller.” The rotary device 2120 is operably connected to a manually operable actuator (such as those manually operable actuators described above) such as through a series of gears. The rotary device 2120 is elongated, such that as each roller turns, it comes into and out of engagement with the fluid line 2110. Due to the arcuate shape of the fluid line 2110, the rotary device 2120 may come into engagement with two sections of the fluid line 2110 at the same time. In alternative embodiments (not shown), the rotary device may have three or more ends that come into engagement with the fluid line.

In the illustrated embodiment, the first end of the rotary device 2120 has a first roller 2130 a rotatably connected thereto and the second end of the rotary device 2120 has a second roller 2130 b rotatably connected thereto. In an alternative embodiment (not shown), the rotary device does not include rollers and its ends directly engage the fluid line.

Rotation of the rotary device 2120 causes a similar peristaltic process as described above with respect to FIG. 20.

FIG. 22 is a schematic illustration of an alternative embodiment of a manual intravenous pump 2200. The manual intravenous pump 2200 includes a fluid line 2220 and may further include a fluid reservoir, such as one of the fluid reservoirs described above in various embodiments.

The manual intravenous pump 2200 further includes a manually operable actuator 2230, such as one of the manually operable actuators described above in various embodiments. Although the illustrated embodiment shows the manually operable actuator 2230 disposed in the same housing as the fluid line 2220, it should be understood that separate housings may be employed, such as those shown in FIGS. 14 and 15.

A piezoelectric system 2240 is operably connected to the manually operable actuator 2230. The piezoelectric system 2240 may include at least one piezoelectric crystal. The piezoelectric system 2240 is further connected to a facilitator 2250. The facilitator 2250 may be any of the devices describe above that facilitates flow of a fluid through a fluid line or through a reservoir. For example, the facilitator may be the rollers 2020 shown in FIG. 20, or the rotary device 2120 shown in FIG. 21.

The piezoelectric system 2240 captures energy supplied by manual actuation of the manually operable actuator 2230. The piezoelectric system 2240 employs the captured energy to regulate a speed at which the facilitator 2250 operates.

The piezoelectric system 2240 is further configured to dissipate the captured energy after cessation of manual actuation of the manually operable actuator 2230. In this manner, no electrical energy will be stored in the manual intravenous pump 2200 when it is not in use. For this reason, the manual intravenous pump 2200 in the illustrated embodiment does not include a battery. However, it should be understood that batteries may be employed in alternative embodiments, and the electrical energy may be stored.

To the extent that the term “includes” or “including” is used in the specification or the claims, it is intended to be inclusive in a manner similar to the term “comprising” as that term is interpreted when employed as a transitional word in a claim. Furthermore, to the extent that the term “or” is employed (e.g., A or B) it is intended to mean “A or B or both.” When the applicants intend to indicate “only A or B but not both” then the term “only A or B but not both” will be employed. Thus, use of the term “or” herein is the inclusive, and not the exclusive use. See, Bryan A. Garner, A Dictionary of Modern Legal Usage 624 (2d. Ed. 1995). Also, to the extent that the terms “in” or “into” are used in the specification or the claims, it is intended to additionally mean “on” or “onto.” Furthermore, to the extent the term “connect” is used in the specification or claims, it is intended to mean not only “directly connected to,” but also “indirectly connected to” such as connected through another component or components.

While the present application has been illustrated by the description of embodiments thereof, and while the embodiments have been described in considerable detail, it is not the intention of the applicants to restrict or in any way limit the scope of the appended claims to such detail. Additional advantages and modifications will readily appear to those skilled in the art. Therefore, the application, in its broader aspects, is not limited to the specific details, the representative apparatus and method, and illustrative examples shown and described. Accordingly, departures may be made from such details without departing from the spirit or scope of the applicant's general inventive concept. 

What is claimed is:
 1. A manual intravenous pump comprising: a first housing having at least one roller disposed therein, the at least one roller being configured to engage a fluid line to facilitate flow of a fluid therethrough; a second housing having: a manually operable actuator; and a piezoelectric system operably connected to the manually operable actuator and operably connected to the at least one roller, wherein the piezoelectric system captures energy supplied by manual actuation of the manually operable actuator, and wherein the piezoelectric system employs the captured energy to regulate a speed at which the at least one roller rotates.
 2. The manual intravenous pump of claim 1, wherein the fluid line is disposed inside the first housing, wherein the fluid line has a first end connected to a first aperture of the first housing and is configured to be connected to an input line, and wherein the fluid line has a second end connected to a second aperture of the first housing and is configured to be connected to an output line.
 3. The manual intravenous pump of claim 1, wherein the first housing has a slot configured to receive the fluid line, wherein the fluid line has a first end connected to a fluid source.
 4. The manual intravenous pump of claim 1, wherein the at least one roller includes a plurality of rollers configured to engage opposing sides of a fluid line.
 5. The manual intravenous pump of claim 1, wherein the at least one roller includes an elongated rotary device having a plurality of sections configured to engage a fluid line at a plurality of locations.
 6. The manual intravenous pump of claim 1, wherein the piezoelectric system is configured to dissipate the captured energy after cessation of manual actuation of the manually operable actuator.
 7. The manual intravenous pump of claim 1, wherein the piezoelectric system includes at least one piezoelectric crystal.
 8. A manually operable pump comprising: a fluid line operatively connected to a fluid source; a manually operable actuator; means for facilitating a flow of fluid from the fluid source through the fluid line, the means for facilitating being operably connected to the manually operable actuator; and a piezoelectric system operably connected to the manually operable actuator, configured to capture energy from manual actuation of the manually operable actuator and regulate a speed of the means for facilitating.
 9. The manually operable pump of claim 8, further comprising a fluid reservoir operably connected to the fluid line.
 10. The manually operable pump of claim 8, wherein the manually operable actuator is a crank.
 11. The manually operable pump of claim 8, wherein the manually operable actuator is a trigger.
 12. The manually operable pump of claim 8, wherein the manually operable actuator includes at least one pivoting handle.
 13. The manually operable pump of claim 8, wherein the means for facilitating includes at least one peristaltic roller.
 14. The manually operable pump of claim 8, further comprising a housing.
 15. The manually operable pump of claim 14, wherein the fluid source is external to the housing.
 16. An intravenous fluid pumping kit comprising: a fluid bag; a fluid line; and a pump including: a housing; at least one roller configured to engage the fluid line, wherein rotation of the at least one roller facilitates a flow of fluid through the fluid line; a manually operable actuator operably connected to the at least one roller, such that manual actuation of the manual operable actuator causes the at least one roller to rotate; and a piezoelectric system operably connected to the manually operable actuator and operably connected to the at least one roller, wherein the piezoelectric system captures energy supplied by manual actuation of the manually operable actuator, and wherein the piezoelectric system employs the captured energy to regulate a speed at which the at least one roller rotates.
 17. The intravenous fluid pumping kit of claim 16, wherein the housing includes a first housing and a second housing.
 18. The intravenous fluid pumping kit of claim 16, wherein the housing includes a slot configured to receive the fluid line.
 19. The intravenous fluid pumping kit of claim 16, wherein the fluid line includes a first fluid line disposed inside the housing, and a second fluid line external to the housing and operably connected to the first fluid line. 